View clinical trials related to Essential Tremor.
Filter by:Combined Phase II/III, multi-center, prospective, single-blinded trial. Ten (10) patients with essential tremor who previously underwent successful and uncomplicated GK thalamotomy for essential tremor will undergo a contralateral treatment. The incidence of side effects will be determined at 3 months postoperatively, graded per the CTCAE v5 and analyzed by a data safety monitoring board. Upon successful review, this Phase II trial will be converted to a Phase III trial of utility that will enrol 40 additional patients. The primary outcome will be the change in QUEST score at 12 months postoperatively, as well as a patient-reported assessment of Health Utility. Secondary outcomes will include objective tremor, gait and speech assessments (filmed and scored by blinded evaluators), as well as quality of life questionnaires and adverse events questionnaires. Outcomes will be assessed at baseline, as well as 3, 6, 12, 24 and 36 months post-operatively.
Radiosurgical thalamotomy on GammaKnife has been shown to be effective in the management of tremors. However, several teams describe a significant risk of severe neurological complications. In addition, fitting the invasive frame and the need to travel to GammKnife centers often limit access to treatment in this population of elderly patients. Linear accelerators have greatly improved their precision, now reaching that of GammaKnife. A possible alternative is therefore to treat patients on linear accelerators, without an invasive frame. The objective of the FRACTHAL study is to assess the feasibility and safety of treatment of essential and / or parkinsonian tremor by fractional radiosurgical thalamotomy on a linear accelerator. The main hypothesis of the FRACTHAL study is based on the fact that dividing the dose into 3 sessions will both protect healthy tissue around the target while maintaining therapeutic efficacy on the treatment target.
Parkinson's disease and essential tremor are chronic movement disorders for which there is no cure. When medication is no longer effective, deep brain stimulation (DBS) is recommended. Standard DBS is a neuromodulation method that uses a simple monophasic pulse, delivered from an electrode to stimulate neurons in a target brain area. This monophasic pulse spreads out from the electrode creating a broad, electric field that stimulates a large neural population. This can often effectively reduce motor symptoms. However, many DBS patients experience side effects - caused by stimulation of non-target neurons - and suboptimal symptom control - caused by inadequate stimulation of the correct neural target. The ability to carefully manipulate the stimulating electric field to target specific neural subpopulations could solve these problems and improve patient outcomes. The use of complex pulse shapes, specifically biphasic pulses and asymmetric pre-pulses, can control the temporal properties of the stimulation field. Evidence suggests that temporal manipulations of the stimulation field can exploit biophysical differences in neurons to target specific subpopulations. Therefore, our aim is to evaluate the effectiveness of complex pulse shapes to reduce side effects and improve symptom control in DBS movement patients.
This study will be a single-centre, prospective, single-arm, open-label, 12-week pilot trial assessing the safety and preliminary efficacy of a second MR-guided focused ultrasound (MRgFUS) thalamotomy on the naïve brain hemisphere after 48 weeks or more of the first MRgFUS thalamotomy in patients with medication-refractory ET. This study will be conducted at the Focused Ultrasound Centre of Excellence at Sunnybrook Health Sciences Centre/University of Toronto.
Pathophysiology of tremor-modulating mechanisms of propranolol and primidone in essential tremor (ET) will be studied using accelerometry with electromyography (EMG), transcranial magnetic stimulation (TMS), and eyeblink conditioning paradigm (EBCC). TMS is a well-established experimental method for studying the effects of drugs on motor cortex excitability. EBCC is a learning paradigm that can be used for studying cerebellar dysfunction since only brainstem and cerebellar functions seem to be needed for this paradigm. The investigators will use TMS to study the mechanisms of primidone and propranolol action in ET, EBCC paradigm to evaluate cerebellar dysfunction in ET patients and to show whether cerebellar dysfunction influences the effectiveness of propranolol and primidone. The investigators will clinically assess patients using The Essential Tremor Rating Assessment Scale (TETRAS) and the Scale for the Assessment and Rating of Ataxia (SARA) scales. Patients with ET will be studied prior to treatment with propranolol or primidone and re-tested 3-6 months after treatment initiation. On each visit, the investigators will clinically assess the patients and perform accelerometry, TMS measurements, and the eyeblink classical conditioning (EBCC) paradigm. The investigators hypothesize that in ET patients, baseline electrophysiological parameters will differ between responders and non-responders to propranolol and primidone and that propranolol and primidone will cause a different pattern of change in electrophysiological parameters among responders. It is hypothesized that cerebellar dysfunction will negatively correlate with patients' response to treatment.
The purpose of this investigation is to determine the optimal DRT/VIM target location and its safety margins based on MR-SISET imaging features by comparing with postoperative lesions and clinical outcomes in patients with tremor who will undergo the MRgFUS tremor therapy.
Parkinson's disease and essential tremor are chronic movement disorders for which there is no cure. When medication is no longer effective, deep brain stimulation (DBS) is recommended. Standard DBS is a neuromodulation method that uses a simple monophasic pulse, delivered from an electrode to stimulate neurons in a target brain area. This monophasic pulse spreads out from the electrode creating a broad, electric field that stimulates a large neural population. This can often effectively reduce motor symptoms. However, many DBS patients experience side effects - caused by stimulation of non-target neurons - and suboptimal symptom control - caused by inadequate stimulation of the correct neural target. The ability to carefully manipulate the stimulating electric field to target specific neural subpopulations could solve these problems and improve patient outcomes. The use of complex pulse shapes, specifically biphasic pulses and asymmetric pre-pulses, can control the temporal properties of the stimulation field. Evidence suggests that temporal manipulations of the stimulation field can exploit biophysical differences in neurons to target specific subpopulations. Therefore, our aim is to evaluate the direct neurophysiological effects of complex pulse shapes in DBS movement disorder patients. This will be achieved using a two-stage investigation: stage one will study the neural response to different pulse shapes using electroencephalography (EEG) recordings. Stage two will study the neural responses to different pulse shapes using intra-operative local field potential (LFP) recordings. This study only relates only to the collection of EEG and LFP recordings in DBS patients. The protocol does not cover any surgical procedures, which already take place as part of the patient's normal clinical care.
Deep Brain Stimulation (DBS) is an effective therapy for patients with medically refractory essential tremor. However, DBS programming is not standardized and multiple clinic visits are frequently required to adequately control symptoms. The investigators aim to longitudinally record brain signals from patients using a novel neurostimulator that can record brain signals. The investigators will correlate brain signals to clinical severity scores to identify pathological rhythms in the absence of DBS, and we will study the effects of DBS on these signals in order to guide clinical programming.
This study's research is devoted to studying the causes of tremor, and especially essential tremor (ET), which is the most common type of tremor. Previous studies have revealed a link between harmane [HA], a dietary neurotoxin, and ET; these studies now also suggest a link between this toxin and Parkinson's disease (PD), a related tremor disorder. Yet these links are tentative rather than conclusively established; therefore, in this new patient-based proposal, which incorporates investigations spanning two continents (North America and Europe), utilizes several complementary study designs (prospective cohort, case control), and draws on several types of tissue (blood, brain), the investigator's goal is to nail down the links between HA and ET and to further solidify the emerging links between HA and PD.
Movement disorders are common neurological disorders, characterized by either excess or paucity of movements. Essential tremor (ET) is one of the most common of these disorders, defined as chronic, rhythmic involuntary movements (tremor) that occur primarily during action involving the upper extremities as prominent body site. ET occurs in between 0.4% and 4% of adults below age 60, its prevalence and related impairment of routine daily actions increasing dramatically with age. More than half of patients do not regain functional independence with medications. These patients are offered functional neurosurgical approaches that carry procedural risk or adverse effects secondary to deep electric stimulation of surgical lesioning. Hence, there is a substantial need for alternative, non-invasive therapeutic options for this disabling neurological disorder. Recently, non-invasive neuromodulation applied as transcranial alternating current stimulation (tACS), has emerged as promising for tremor control. In healthy subjects, tACS applied with a high definition (or focused) montage to the primary motor cortex (M1), was found to entrain physiological tremor; in patients with Parkinson's disease, tACS could decrease the amplitude of rest tremor when the stimulation was delivered in phase with, and at the same frequency of, the tremor. Tremor in ET could also be entrained applying ACS to the arm skin's peripheral nerves (transcutaneous ACS), but its effect on tremor amplitude is unknown. METHODS AND POTENTIAL CONTRIBUTION/IMPACT OF THE RESEARCH. The proposed project aims to explore the whole potential of tACS for the tremor suppression in ET. The investigators aim to test the following hypotheses: 1. focused (or high definition, HD) tACS delivered over M1 at the same frequency of the tremor is effective in decreasing tremor amplitude in ET; 2. this effect is strongest when the delivery of tACS is locked to the phase of the tremor expressed by the patient, i.e. administering tACS in a closed-loop modality; 3. transcutaneous ACS in the upper extremities is as effective as tACS applied to the scalp around M1.